RU2296196C2 - Device to relief excessive air pressure in sewage system - Google Patents

Abstract

FIELD: means to relief short air pressure pulses in drain or sewage systems.

SUBSTANCE: device comprises body to be connected to sewage system and elastic reservoir secured to the body. The elastic body expands during short air pressure increase in sewage system and comprises inlet and outlet pipes connected with each other by intermediate members. The intermediate members are located in central body part. Elastic reservoir and at least one body part are enclosed with outer shell.

EFFECT: provision of excessive air pressure reduction without discharge of foul hydrogen sulfide containing air into atmosphere.

10 cl, 4 dwg

Description

The present invention relates to a device for reducing short-term pulses of excessive air pressure in drainage or sewer systems.

In such drainage systems and, in particular, in sewage systems of buildings with at least three floors, air valves are usually used that prevent stale hydrogen sulfide-containing air from escaping from the system and ensure that outside air enters the system when pressure drops in the discharge and exhaust pipes . Such valves are described, for example, in GB 2014697, EP 0084303, EP 0278746 or EP 1026329.

However, the use of such valves prevents the free exit of air into the atmosphere during short-term increases in excess air pressure that occur in the sewage system and adversely affects the operation of the system.

EP 0172966 and EP 0661483 describe safety valves for sewage systems that automatically open when the waste and waste water moves in the opposite direction and the pressure in the system rises.

When using such valves, the pressure release or decrease in the sewage system occurs as a result of the release of air in the system into the atmosphere.

Obviously, the reduction of excess air pressure short-term in the system should not be accompanied by the entry into the atmosphere of stagnant air containing hydrogen sulfide in the system.

The present invention provides a device for depressurizing a drainage system for use in a building sewage system and comprising a housing connected to a sewage system, to which an elastic reservoir is attached, which swells when the overpressure of the air in the sewage system increases for a short time and has an inlet and an outlet nozzles interconnected by intermediate parts located in the middle part of the housing, the elastic tank and at least part of the housing closed by an outer casing.

In one of the preferred embodiments of the invention, ventilation holes are provided in the outer casing through which the inner cavity of the casing in which the elastic reservoir is constantly in communication with the atmosphere to protect the elastic reservoir from damage.

To increase the tightness of the device, its body is made of the corresponding rigid material. The casing is made in the form of one continuous piece, to which an elastic reservoir is attached externally. In the place where the elastic reservoir closes the case made of rigid material from the outside, ventilation holes can be located through which air from the drainage system can freely pass into the reservoir and exit from it outside. The hard case of the device can be made, for example, from polyvinyl chloride (PVC). It is advisable that the elastic tank covers the middle part of the housing, including the intermediate parts, and is attached to the inlet and outlet nozzles by means of a mounting device.

In a preferred embodiment of the device according to the invention, the elastic reservoir is located inside the outer casing and is hermetically attached to the inlet and outlet pipes of the housing using round rings or other elastic fastening devices and a suitable sealant, for example, paste from unvulcanized butyl rubber and a solvent. A round ring presses the elastic reservoir against the outer surface of the inlet or outlet, onto which a paste of unvulcanized butyl rubber and solvent is preliminarily applied for complete sealing. The elastic reservoir is preferably made of dense butyl rubber with a thickness of about 0.2 mm.

In a preferred embodiment of the device, the outer casing may be cylindrical in shape, and ventilation openings may be made in the bottom wall of the outer casing. The outer casing can be made of a certain hard material, for example, PVC.

The housing of the device in a preferred embodiment has an upper part that is hermetically sealed by a cap.

In one embodiment of the invention, only one, made in the form of a “riser” device of the invention is used to relieve air pressure in the sewage system. In another embodiment, to increase throughput, the outlet pipe of one pressure relief device is connected to the inlet pipe of a second same device. In addition to these two options, the invention proposes another option in which, to improve the quality of the drainage system, the pressure relief device or devices are used together with an inlet valve through which ambient air enters the system.

Below, the device proposed in the invention is considered in more detail by the example of one of the options for its possible implementation with reference to the accompanying drawings, which show:

figure 1 is a cross section of a device for relieving pressure,

figure 2 is a transverse section of the housing of the device,

figure 3 is a schematic illustration of a device casing in a perspective view and

figure 4 is a transverse section of two connected in series devices for pressure relief.

The pressure relief device 1 shown in the drawings consists of an outer casing 2, a housing 3, an elastic reservoir 10 and a cap 16. In FIG. 1, a pressure relief device is shown assembled. The elastic reservoir 10 closes the middle part of the housing and is attached to the inlet and outlet nozzles 6 and 4 by round rings 8. To seal the elastic reservoir, a layer of sealant (not shown) is applied to the nozzles 6 and 4, to which the edges of the reservoir are pressed tightly with rings. Such fastening of the elastic reservoir 10 to the housing ensures its complete tightness.

The inlet and outlet nozzles 6 and 4 of the housing 3 are interconnected by intermediate parts 12 in the form of dividing plates, between which there is free space, closed outside by an elastic tank 10.

The inlet pipe 6 communicates with the drainage system. When a short pulse of air pressure occurs in the drainage system, air pressure from the drainage system will spread through the open space between the separation plates 12 and inflate the elastic reservoir 10, as shown in FIG. The elastic tank 10 does not allow air from the drainage system to the atmosphere, since it is hermetically attached using round rings 8 to the housing 3 in the area of the inlet 6 and 4 outlet pipes of the latter, and the internal volume of the housing is isolated from the surrounding atmosphere by a cap 16 mounted on the outlet pipe 4 cases 3.

The outer casing 2 partially closes the casing 3 and completely closes the elastic reservoir 10. The outer casing, which has, in particular, ventilation holes 20 made in particular in its lower wall 22, through which the inner cavity of the casing is constantly in communication with the atmosphere, reliably protects the elastic reservoir 10 from possible damage due to any external exposure.

The device 1 for relieving pressure is attached to the drainage system by a transitional coupling 18. The transitional coupling 18 allows you to connect pipes with different diameters and can be made, for example, of an elastomer.

As shown in figure 2, the housing 3 proposed in the invention of the device consists of four different parts. The housing has an upper part 14, which is adjacent to the outlet pipe 4, connected to the inlet pipe 6 by intermediate parts or separation plates 12. The separation plates 12 allow air to pass through the pressure relief device 1 with a fully compressed elastic reservoir 10.

Figure 3 schematically shows the housing 3 without the upper part 14. As shown in figure 3, the separation plates are not located around the entire circumference of the housing 3. The presence of a gap between the separation plates 12 allows air to pass from the drainage system into the elastic reservoir 10, which the presence of excess pressure in the system is inflated and absorbs energy that briefly arises in the system during a hydraulic shock of a longitudinal pressure wave.

Figure 4 shows two series-connected devices 1 for pressure relief. The devices are interconnected by a transitional coupler 18, mounted on the inlet pipe 6 of the upper pressure relief device 5 and inserted into the upper part 14 of the lower pressure relief device 7.

Obviously, the connection of the two pressure relief devices or the pressure relief device and the sewage system, or the connection of the pressure relief device and the air inlet valve must be in a tight fit, providing the necessary tightness of the system.

Proposed in the present invention, a simple and effective device for relieving pressure can be used in existing sewer (drainage) systems.

It is obvious that the above one of specific examples of a possible embodiment of the invention does not exclude the possibility of making various changes and improvements to it. The possibility of such changes and improvements is not excluded by the claims, which fully reflects and protects the scope of the invention.

Claims (10)

1. Device (1) for reducing excess air pressure, intended for use in the sewage system of a building and containing a housing (3) connected to the sewage system, to which an elastic reservoir (10) is attached, which swells when the excess air pressure in the sewage system increases for a short time, and which has an inlet (6) and an outlet (4) nozzles interconnected by intermediate parts (12) located in the middle part of the housing (3), and the elastic reservoir (10) and at least part of the housing (3) are closed on een outdoor casing (2). 2. The device according to claim 1, in which in the outer casing (2) there are ventilation holes (20) through which the inner cavity of the casing in which the elastic reservoir (10) is located is constantly in communication with the atmosphere while protecting the elastic reservoir (10) from damage. 3. The device according to claim 2, in which the elastic reservoir (10) closes the middle part of the housing (3, 4, 6), including intermediate parts (12), and is attached to the inlet (6) and outlet (4) nozzles by means of a mounting device (8). 4. The device according to claim 3, in which the mounting device is at least one round ring (8). 5. The device according to claim 3, in which the mounting device (8) is used together with the sealant. 6. The device according to claim 5, in which a paste of unvulcanized butyl rubber and a solvent is used as a sealant. 7. The device according to claim 1, in which the elastic reservoir (10) is made of butyl rubber. 8. The device according to claim 2, in which the outer casing (2) has a cylindrical shape, and the ventilation holes (20) are made in the lower wall (22) of the outer casing (2). 9. The device according to claim 1, in which the housing (3, 4, 6) has an upper part (14) hermetically sealed by a cap (16). 10. Sewer system containing at least one device (1) for reducing excess air pressure according to claim 1.

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